hypothesis-generation

jimmc414/hypothesis-generation

Research

413

About

SKILL.md

hypothesis-generation

jimmc414/hypothesis-generation

Research

413

About

Generate testable hypotheses. Formulate from observations, design experiments, explore competing explanations, develop predictions, propose mechanisms, for scientific inquiry across domains.

SKILL.md

Scientific Hypothesis Generation

Overview

Hypothesis generation is a systematic process for developing testable explanations. Formulate evidence-based hypotheses from observations, design experiments, explore competing explanations, and develop predictions. Apply this skill for scientific inquiry across domains.

When to Use This Skill

This skill should be used when:

Developing hypotheses from observations or preliminary data
Designing experiments to test scientific questions
Exploring competing explanations for phenomena
Formulating testable predictions for research
Conducting literature-based hypothesis generation
Planning mechanistic studies across scientific domains

Workflow

Follow this systematic process to generate robust scientific hypotheses:

1. Understand the Phenomenon

Start by clarifying the observation, question, or phenomenon that requires explanation:

Identify the core observation or pattern that needs explanation
Define the scope and boundaries of the phenomenon
Note any constraints or specific contexts
Clarify what is already known vs. what is uncertain
Identify the relevant scientific domain(s)

2. Conduct Comprehensive Literature Search

Search existing scientific literature to ground hypotheses in current evidence. Use both PubMed (for biomedical topics) and general web search (for broader scientific domains):

For biomedical topics:

Use WebFetch with PubMed URLs to access relevant literature
Search for recent reviews, meta-analyses, and primary research
Look for similar phenomena, related mechanisms, or analogous systems

For all scientific domains:

Use WebSearch to find recent papers, preprints, and reviews
Search for established theories, mechanisms, or frameworks
Identify gaps in current understanding

Search strategy:

Begin with broad searches to understand the landscape
Narrow to specific mechanisms, pathways, or theories
Look for contradictory findings or unresolved debates
Consult references/literature_search_strategies.md for detailed search techniques

3. Synthesize Existing Evidence

Analyze and integrate findings from literature search:

Summarize current understanding of the phenomenon
Identify established mechanisms or theories that may apply
Note conflicting evidence or alternative viewpoints
Recognize gaps, limitations, or unanswered questions
Identify analogies from related systems or domains

4. Generate Competing Hypotheses

Develop 3-5 distinct hypotheses that could explain the phenomenon. Each hypothesis should:

Provide a mechanistic explanation (not just description)
Be distinguishable from other hypotheses
Draw on evidence from the literature synthesis
Consider different levels of explanation (molecular, cellular, systemic, population, etc.)

Strategies for generating hypotheses:

Apply known mechanisms from analogous systems
Consider multiple causative pathways
Explore different scales of explanation
Question assumptions in existing explanations
Combine mechanisms in novel ways

5. Evaluate Hypothesis Quality

Assess each hypothesis against established quality criteria from references/hypothesis_quality_criteria.md:

Testability: Can the hypothesis be empirically tested? Falsifiability: What observations would disprove it? Parsimony: Is it the simplest explanation that fits the evidence? Explanatory Power: How much of the phenomenon does it explain? Scope: What range of observations does it cover? Consistency: Does it align with established principles? Novelty: Does it offer new insights beyond existing explanations?

Explicitly note the strengths and weaknesses of each hypothesis.

6. Design Experimental Tests

For each viable hypothesis, propose specific experiments or studies to test it. Consult references/experimental_design_patterns.md for common approaches:

Experimental design elements:

What would be measured or observed?
What comparisons or controls are needed?
What methods or techniques would be used?
What sample sizes or statistical approaches are appropriate?
What are potential confounds and how to address them?

Consider multiple approaches:

Laboratory experiments (in vitro, in vivo, computational)
Observational studies (cross-sectional, longitudinal, case-control)
Clinical trials (if applicable)
Natural experiments or quasi-experimental designs

7. Formulate Testable Predictions

For each hypothesis, generate specific, quantitative predictions:

State what should be observed if the hypothesis is correct
Specify expected direction and magnitude of effects when possible
Identify conditions under which predictions should hold
Distinguish predictions between competing hypotheses
Note predictions that would falsify the hypothesis

8. Present Structured Output

Use the template in assets/hypothesis_output_template.md to present hypotheses in a clear, consistent format:

Standard structure:

Background & Context - Phenomenon and literature summary
Competing Hypotheses - Enumerated hypotheses with mechanistic explanations
Quality Assessment - Evaluation of each hypothesis
Experimental Designs - Proposed tests for each hypothesis
Testable Predictions - Specific, measurable predictions
Critical Comparisons - How to distinguish between hypotheses

Quality Standards

Ensure all generated hypotheses meet these standards:

Evidence-based: Grounded in existing literature with citations
Testable: Include specific, measurable predictions
Mechanistic: Explain how/why, not just what
Comprehensive: Consider alternative explanations
Rigorous: Include experimental designs to test predictions

Resources

references/

hypothesis_quality_criteria.md - Framework for evaluating hypothesis quality (testability, falsifiability, parsimony, explanatory power, scope, consistency)
experimental_design_patterns.md - Common experimental approaches across domains (RCTs, observational studies, lab experiments, computational models)
literature_search_strategies.md - Effective search techniques for PubMed and general scientific sources

assets/

hypothesis_output_template.md - Structured format for presenting hypotheses consistently with all required sections

About

SKILL.md

About

Generate testable hypotheses. Formulate from observations, design experiments, explore competing explanations, develop predictions, propose mechanisms, for scientific inquiry across domains.

SKILL.md

Scientific Hypothesis Generation

Overview

When to Use This Skill

This skill should be used when:

Developing hypotheses from observations or preliminary data
Designing experiments to test scientific questions
Exploring competing explanations for phenomena
Formulating testable predictions for research
Conducting literature-based hypothesis generation
Planning mechanistic studies across scientific domains

Workflow

Follow this systematic process to generate robust scientific hypotheses:

1. Understand the Phenomenon

Start by clarifying the observation, question, or phenomenon that requires explanation:

Identify the core observation or pattern that needs explanation
Define the scope and boundaries of the phenomenon
Note any constraints or specific contexts
Clarify what is already known vs. what is uncertain
Identify the relevant scientific domain(s)

2. Conduct Comprehensive Literature Search

Search existing scientific literature to ground hypotheses in current evidence. Use both PubMed (for biomedical topics) and general web search (for broader scientific domains):

For biomedical topics:

Use WebFetch with PubMed URLs to access relevant literature
Search for recent reviews, meta-analyses, and primary research
Look for similar phenomena, related mechanisms, or analogous systems

For all scientific domains:

Use WebSearch to find recent papers, preprints, and reviews
Search for established theories, mechanisms, or frameworks
Identify gaps in current understanding

Search strategy:

Begin with broad searches to understand the landscape
Narrow to specific mechanisms, pathways, or theories
Look for contradictory findings or unresolved debates
Consult references/literature_search_strategies.md for detailed search techniques

3. Synthesize Existing Evidence

Analyze and integrate findings from literature search:

Summarize current understanding of the phenomenon
Identify established mechanisms or theories that may apply
Note conflicting evidence or alternative viewpoints
Recognize gaps, limitations, or unanswered questions
Identify analogies from related systems or domains

4. Generate Competing Hypotheses

Develop 3-5 distinct hypotheses that could explain the phenomenon. Each hypothesis should:

Provide a mechanistic explanation (not just description)
Be distinguishable from other hypotheses
Draw on evidence from the literature synthesis
Consider different levels of explanation (molecular, cellular, systemic, population, etc.)

Strategies for generating hypotheses:

Apply known mechanisms from analogous systems
Consider multiple causative pathways
Explore different scales of explanation
Question assumptions in existing explanations
Combine mechanisms in novel ways

5. Evaluate Hypothesis Quality

Assess each hypothesis against established quality criteria from references/hypothesis_quality_criteria.md:

Explicitly note the strengths and weaknesses of each hypothesis.

6. Design Experimental Tests

For each viable hypothesis, propose specific experiments or studies to test it. Consult references/experimental_design_patterns.md for common approaches:

Experimental design elements:

What would be measured or observed?
What comparisons or controls are needed?
What methods or techniques would be used?
What sample sizes or statistical approaches are appropriate?
What are potential confounds and how to address them?

Consider multiple approaches:

Laboratory experiments (in vitro, in vivo, computational)
Observational studies (cross-sectional, longitudinal, case-control)
Clinical trials (if applicable)
Natural experiments or quasi-experimental designs

7. Formulate Testable Predictions

For each hypothesis, generate specific, quantitative predictions:

State what should be observed if the hypothesis is correct
Specify expected direction and magnitude of effects when possible
Identify conditions under which predictions should hold
Distinguish predictions between competing hypotheses
Note predictions that would falsify the hypothesis

8. Present Structured Output

Use the template in assets/hypothesis_output_template.md to present hypotheses in a clear, consistent format:

Standard structure:

Background & Context - Phenomenon and literature summary
Competing Hypotheses - Enumerated hypotheses with mechanistic explanations
Quality Assessment - Evaluation of each hypothesis
Experimental Designs - Proposed tests for each hypothesis
Testable Predictions - Specific, measurable predictions
Critical Comparisons - How to distinguish between hypotheses

Quality Standards

Ensure all generated hypotheses meet these standards:

Evidence-based: Grounded in existing literature with citations
Testable: Include specific, measurable predictions
Mechanistic: Explain how/why, not just what
Comprehensive: Consider alternative explanations
Rigorous: Include experimental designs to test predictions

Resources

references/

hypothesis_quality_criteria.md - Framework for evaluating hypothesis quality (testability, falsifiability, parsimony, explanatory power, scope, consistency)
experimental_design_patterns.md - Common experimental approaches across domains (RCTs, observational studies, lab experiments, computational models)
literature_search_strategies.md - Effective search techniques for PubMed and general scientific sources

assets/

hypothesis_output_template.md - Structured format for presenting hypotheses consistently with all required sections